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The Mote Revolution: Low Power Wireless Sensor Network Devices

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Presentation on theme: "The Mote Revolution: Low Power Wireless Sensor Network Devices"— Presentation transcript:

1 The Mote Revolution: Low Power Wireless Sensor Network Devices
University of California, Berkeley Joseph Polastre Robert Szewczyk Cory Sharp David Culler

2 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Outline Trends and Applications Mote History and Evolution Design Principles Telos “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

3 Faster, Smaller, Numerous
Moore’s Law “Stuff” (transistors, etc) doubling every 1-2 years Bell’s Law New computing class every 10 years Streaming Data to/from the Physical World log (people per computer) year “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

4 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Applications Sample Rate & Precision Disconnection & Lifetime Density & Scale Low Latency Mobility Environmental Monitoring Habitat Monitoring Integrated Biology Structural Monitoring Interactive and Control Pursuer-Evader Intrusion Detection Automation “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

5 Open Experimental Platform
Telos 4/04 Robust Low Power 250kbps Easy to use Services Networking TinyOS Small microcontroller kB code B data Simple, low-power radio kbps ASK EEPROM (32 KB) Simple sensors WeC 99 “Smart Rock” Rene 11/00 Designed for experimentation sensor boards power boards Mica 1/02 NEST open exp. Platform 128 kB code, 4 kB data 40kbps OOK/ASK radio 512 kB Flash Dot 9/01 Demonstrate scale Mica2 12/02 38.4kbps radio FSK Before we jump in to the technical material, I would like to give you one more bit of context. Spec 6/03 “Mote on a chip” Commercial Off The Shelf Components (COTS) “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

6 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Mote Evolution “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

7 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Low Power Operation Efficient Hardware Integration and Isolation Complementary functionality (DMA, USART, etc) Selectable Power States (Off, Sleep, Standby) Operate at low voltages and low current Run to cut-off voltage of power source Efficient Software Fine grained control of hardware Utilize wireless broadcast medium Aggregate “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

8 Typical WSN Application
processing data acquisition communication Periodic Data Collection Network Maintenance Majority of operation Triggered Events Detection/Notification Infrequently occurs But… must be reported quickly and reliably Long Lifetime Months to Years without changing batteries Power management is the key to WSN success Power wakeup sleep Time “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

9 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Design Principles Key to Low Duty Cycle Operation: Sleep – majority of the time Wakeup – quickly start processing Active – minimize work & return to sleep “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

10 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Sleep Majority of time, node is asleep >99% Minimize sleep current through Isolating and shutting down individual circuits Using low power hardware Need RAM retention Run auxiliary hardware components from low speed oscillators (typically 32kHz) Perform ADC conversions, DMA transfers, and bus operations while microcontroller core is stopped “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

11 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Wakeup Overhead of switching from Sleep to Active Mode Microcontroller Radio (FSK) 292 ns 10ns – 4ms typical 2.5 ms 1– 10 ms typical “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

12 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Active Microcontroller Fast processing, low active power Avoid external oscillators Radio High data rate, low power tradeoffs Narrowband radios Low power, lower data rate, simple channel encoding, faster startup Wideband radios More robust to noise, higher power, high data rates External Flash (stable storage) Data logging, network code reprogramming, aggregation High power consumption Long writes Radio vs. Flash 250kbps radio sending 1 byte Energy : 1.5mJ Duration : 32ms Atmel flash writing 1 byte Energy : 3mJ Duration : 78ms “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

13 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Telos Platform A new platform for low power research Monitoring applications: Environmental Building Tracking Long lifetime, low power, low cost Built from application experiences and low duty cycle design principles Robustness Integrated antenna Integrated sensors Soldered connections Standards Based IEEE USB CC2420 radio 250kbps 2.4GHz ISM band TI MSP430 Ultra low power 1.6mA sleep 460mA active 1.8V operation Open embedded platform with open source tools, operating system (TinyOS), and designs. “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

14 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Low Power Operation TI MSP Advantages over previous motes 16-bit core 12-bit ADC 16 conversion store registers Sequence and repeat sequence programmable < 50nA port leakage (vs. 1mA for Atmels) Double buffered data buses Interrupt priorities Calibrated DCO Buffers and Transistors Switch on/off each sensor and component subsystem “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

15 Minimize Power Consumption
Compare to MicaZ: a Mica2 mote with AVR mcu and radio Sleep Majority of the time Telos: 2.4mA MicaZ: 30mA Wakeup As quickly as possible to process and return to sleep Telos: 290ns typical, 6ms max MicaZ: 60ms max internal oscillator, 4ms external Active Get your work done and get back to sleep Telos: 4-8MHz 16-bit MicaZ: 8MHz 8-bit “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

16 CC2420 Radio IEEE 802.15.4 Compliant
Fast data rate, robust signal 250kbps : 2Mchip/s : DSSS 2.4GHz : Offset QPSK : 5MHz 16 channels in -94dBm sensitivity Low Voltage Operation 1.8V minimum supply Software Assistance for Low Power Microcontrollers 128byte TX/RX buffers for full packet support Automatic address decoding and automatic acknowledgements Hardware encryption/authentication Link quality indicator (assist software link estimation) samples error rate of first 8 chips of packet (8 chips/bit) “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

17 Power Calculation Comparison Design for low power
Mica2 (AVR) 0.2 ms wakeup 30 mW sleep 33 mW active 21 mW radio 19 kbps 2.5V min 2/3 of AA capacity MicaZ (AVR) 0.2 ms wakeup 30 mW sleep 33 mW active 45 mW radio 250 kbps 2.5V min 2/3 of AA capacity Telos (TI MSP) 0.006 ms wakeup 2 mW sleep 3 mW active 45 mW radio 250 kbps 1.8V min 8/8 of AA capacity Supporting mesh networking with a pair of AA batteries reporting data once every 3 minutes using synchronization (<1% duty cycle) 453 days 328 days 945 days “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

18 Integrated Antenna Inverted-F Microstrip Antenna and SMA Connector
Psuedo Omnidirectional 50m range indoors 125m range outdoors Optimum at MHz SMA Connector Enabled by moving a capacitor > 125m range Optimum at MHz “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

19 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Sensors Integrated Sensors Sensirion SHT11 Humidity (3.5%) Temperature (0.5oC) Digital sensor Hamamatsu S1087 Photosynthetically active light Silicon diode Hamamatsu S1337-BQ Total solar light Expansion 6 ADC channels 4 digital I/O Existing sensor boards Magnetometer Ultrasound Accelerometer 4 PIR sensors Microphone Buzzer dot mag ultrasound acoustic “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

20 “The Mote Revolution: Low Power Wireless Sensor Network Devices”
Conclusions New design approach derived from our experience with resource constrained wireless sensor networks Active mode needs to run quickly to completion Wakeup time is crucial for low power operation Wakeup time and sleep current set the minimal energy consumption for an application Sleep most of the time Tradeoffs between complexity/robustness and low power radios Careful integration of hardware and peripherals “The Mote Revolution: Low Power Wireless Sensor Network Devices” Hot Chips 2004 : Aug 22-24, 2004

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